文档简介
MEMSVACUUMPACKAGINGTECHNOLOGYANDAPPLICATIONSJINYUFENG,ZHANGJIAXUNPEKINGUNIVERSITYSHENZHENGRADUATESCHOOL,SHENZHEN,518055,CHINANATIONALKEYLABOFMICRO/NANOFABRICATIONTECHNOLOGYOFCHINATEL861062752536,FAX861062751789,JINYFIMEPKUEDUCNABSTRACTMANYMEMSMICROELECTROMECHANICSYSTEMSPARTSHAVETOMEETTHEREQUIREMENTSFORVACUUMPACKAGINGINVACUUMPACKAGING,LEAKAGEANDGASPERMEATION,WHICHWILLAFFECTTHENORMALFUNCTIONOFTHECOMPONENTS,AREMAJORPROBLEMSHERMETICSEALINGISONEOFTHEMOSTIMPORTANTTECHNOLOGIESFORRELIABLEVACUUMPACKAGINGINTHISPAPER,SEVERALHERMETICSEALINGTECHNOLOGIESFORVACUUMPACKAGINGWILLBEPRESENTED,INCLUDINGEUTECTICBONDING,ADHESIVEBONDING,GLASSFRITBONDING,ANDSILICONGLASSANODICBONDINGFURTHERFORE,THEAUTHORWILLINTRODUCEDTWOAPPROACHESTODEALWITHSEALINGIMPERFECTSURFACECAUSEDBYELECTRICFEEDTHROUGHS,WHICHLINKTOTHEOUTSIDEOFTHESMALLCAVITYOFMEMSSENSORSTHEGETTERWILLBEDISDUSSEDASITISESSENTIALTOKEEPTHEVACUUMENVIRONMENTINSIDETHECAVITYOFDEVICESINCETHEINNERWALLSMIGHTRELEASEGASAFTERHERMETICSEAL1MATERIALSUSEDINMEMSVACUUMPACKAGING1GASPERMEATIONINVACUUMPACKAGINGHASTOBECONSIDERED,WHENCHOOSINGMATERIALSAPPLIEDINMEMSPACKAGINGFORTHESAMEQUANTITYPERMEATEDGAS,THEPRESSUREDETERIORATIONCAUSEDBYGASPERMEATIONINMEMSISMUCHMORETHANTHATINCONVENTIONALSTRUCTURE,SINCETHEVOLUMEISSMALLERINMEMSCAVITYFURTHERMORE,THINNERSTRUCTURESAREOFTENUSEDINMEMSVACUUMPACKAGINGTHISWILLCAUSEMORESERIOUSPERMEATIONPROBLEMFORTHEMEMSDEVICESFORINSTANCE,THEPERMEATEDGASISHUNDREDTIMESMOREWHENTHETHICKNESSOFAWALLORDIAPHRAGMISREDUCEDFROM1MMTO10MINCASEOFTHEGASPERMEATION,WESHOULDCHOOSETHEPACKAGINGMATERIALSWITHLOWPERMEATIONRATEFIG1COMPARESTHEPERMEATIONRATEOFMOISTUREORWATERMOLECULESTHROUGHSEVERALKINDSOFPACKAGINGMATERIALS,WHICHAREUSEDINMODERNELECTRONICFABRICATIONANDPACKAGINGTHEIRPERMEATIONRATERANGESFROM1018CM3/SECTO1010CM3/SECFIG1PERMEABILITYOFWATERTHROUGHNONHERMETICANDHERMETICMATERIALSFEATURINGLOWERPERMEATIONRATE,GLASSES,CERAMICS,SILICONNITRIDES,METALS,ANDSOMEPURECRYSTALSARESUGGESTEDTOBETHECANDIDATESFORHERMETICPACKAGINGTHOSEWITHHIGHERPERMEATIONRATE,WHICHAREREGARDEDASNONHERMETICMATERIALS,MUSTBEKEPTAWAYFROMTHECATALOGUEFORHERMETICPACKAGINGINOURWORKS,GLASS,CERAMIC,ANDADHESIVEMATERIALSWITHLOWPERMEATIONRATEWERECHOSENASTHEPACKAGINGSTRUCTURES/MATERIALS2HERMETICALSEALINGFORMEMSSTRUCTUREHERMETICPACKAGINGPLAYSANIMPORTANTROLEINMANYMICROSYSTEMSHERMETICSEALING,WHICHPROTECTSTHEMICROSYSTEMSFROMHARMFULENVIRONMENTALINFLUENCES,CANSIGNIFICANTLYINCREASETHERELIABILITYANDLIFETIMEOFTHEMBESIDESANODICBONDING,ANUMBEROFOTHERBONDINGTECHNIQUESHAVEALSOBEENUSEDFORHERMETICPACKAGING,INCLUDINGSILICONTOGOLDEUTECTICBONDING,GLASSFRITBONDING,FUSIONBONDING,ANDBONDINGUSINGEVAPORATEDGLASSTHEHERMETICSEALINGPROCESSESDEVELOPEDINTHISRESEARCHWORKINCLUDEELECTROSTATICBONDINGORANODICSILICONGLASSBONDING,EUTECTICBONDING,GLASSFRITBONDING21SOLDERBONDINGANDEUTECTICBONDINGSOLDERBONDINGFORHERMETICALLYSEALINGWAFERSISBASEDONSOLDERJOININGTWOWAFERTOGETHEROFTHEM,EUTECTICBONDINGISWIDELYAPPLIEDINMEMSPACKAGING,WHICHTAKESTHEADVANTAGEOFTHEEUTECTICALLOYTOREALIZEABONDBETWEENTWOSUBSTRATESATALOWERTEMPERATURESOLDEROFASUITABLEMATERIALSETCANBEFORMEDINTHEBONDINGAREABETWEENSUBSTRATESOFPACKAGEANDDEVICERAISETHETEMPERATUREUNTILTHESOLDERFLOWSANDCREATESABONDTOSEALTWOSUBSTRATESTHEMOSTOBVIOUSMATERIALSTOUSEARETHOSESTANDARDSOLDERSUSEDINMICROELECTRONICAPPLICATIONS,BUTMANYOFSUCHSOLDERMATERIALSCONTAINEITHERFLUXORSUFFICIENTIMPURITIESTHESEFLAWSCAUSESIGNIFICANTOUTGASSINGDURINGTHEREFLOWPROCESSTHISBECOMESAMAJORPROBLEMWHENTRYINGTOUSESUCHSOLDERSFORVACUUMPACKAGINGRECENTDEVELOPMENTRESEARCHONNEWFLUXLESSSOLDERMATERIALSMAYOVERCOMESUCHPROBLEMANDSEVERALGROUPSAREPURSUINGTHIS2COMPARINGWITHSTANDARDSOLDER,ITISALSOPOSSIBLETOUSEALLOYSOFDIFFERENTMATERIALSINTHEFORMOFEUTECTICSOLDERONEOFTHEMOSTCOMMONMATERIALSETSISTHEEUTECTICOFGOLDANDSILICONSILICONGOLDEUTECTICISQUITEATTRACTIVEBECAUSEITISFORMEDATATEMPERATUREOF363CWITHONEPARTSILICONANDFOURPARTSGOLDTHISMATERIALSISCOMMONLYUSEDINMEMSFABRICATION,ANDWHENTHEEUTECTICISFORMED,THEOUTGASSINGPROBLEMISRESOLVEDSINCETHEMIXTUREISSIMPLYFORMEDBYRAISINGTHETEMPERATUREANDTHESTARTINGMATERIALSAREPUREINADDITION,THETEMPERATUREISLOWENOUGHFORMOSTAPPLICATIONS0780394496/05/20002005IEEE20056THINTERNATIONALCONFERENCEONELECTRONICPACKAGINGTECHNOLOGYONONEHAND,FORSILICONGOLDEUTECTICBONDING,ALTHOUGHTHEEUTECTICPOINTIS363OC,THEBONDINGTEMPERATUREMUSTBEHIGHERAHIGHERTEMPERATURECANPROMOTETHEDIFFUSIONOFGOLDANDSILICONINTOEACHOTHER,ANDINCREASETHETHICKNESSOFTHEDIFFUSIONLAYERWHERETHECHEMICALCOMPOSITIONCANMATCHWITHWHATISNEEDEDFOREUTECTICBONDINGTHEREFORE,AHIGHERTEMPERATUREANDALONGERBONDINGTIMEAREBENEFICIALTOAGOODBONDINGONTHEOTHERHAND,IFTHEBONDINGTEMPERATUREISTOOHIGH,ITMAYCAUSESERIOUSDIFFUSIONOFGOLDINTOSILICON,WHICHWILLDEGRADETHEFUNCTIONOFTHESILICONDEVICESFIG2SHOWSTHESCANNINGACOUSTICMICROSCOPESAMMICROGRAPHSOFEUTECTICALLYBONDEDSENSORWAFERANDSILICONCAPWAFERATABONDINGTEMPERATUREOF400450OCDURINGSAMANALYZINGPROCESS,THEBONDEDWAFERSAREIMMERSEDINDEIONIZEDWATERBUBBLEFREEINTERFACESAREOBSERVEDANDNOWATERISSUCKEDINTOTHECAVITIESITINDICATESTHATTHECAVITIESAREWELLSEALEDTHEPULLTESTRESULTSSHOWTHATTHEBONDSTRENGTHISMORETHAN5MPAFIG2SAMMICROGRAPHSOFSEALEDWAFERS22ADHESIVEBONDINGTHEADVANTAGESOFADHESIVEBONDINGAREITSLOWPROCESSTEMPERATUREANDTHEPOSSIBILITYTOJOINDIFFERENTMATERIALS3THISBONDINGTECHNOLOGYMAKESUSEOFANINTERMEDIATEADHESIVELAYERTOJOINTWOSUBSTRATEMATERIALSWITHDIFFERENTPROPERTIESTHEADHESIVEMATERIALSMAYBEEPOXIESORPOLYMERSSOMETIMESEPOXYISACCEPTABLEFORGASFILLEDMEMSDEVICEFORINSTANCE,EPOXYISUSEDINMICROOPTICALSWITCHFORHOLDINGOPTICALCOMPONENTSTOGETHERHOWEVER,EPOXYINTHELIGHTPATHISNOTDESIRABLEASITMAYAGE,DRIFT,ORCRACKATHIGHLASERPOWERLEVELSTHISCAUSESASIGNIFICANTPROBLEMFORTHEPACKAGE,SINCETHEPACKAGEHASTOPROTECTTHEDEVICEANDSIMULTANEOUSLY,PROVIDEACCESSTOTHEENVIRONMENTTHATTHEDEVICEISSUPPOSEDTOCONTACTWITHASARESULT,ALOTOFEFFORTHASBEENEXPENDEDONDEVELOPINGTHEPROPERPROTECTION/ENCAPSULATIONMEDIUMFORMEMSFIG3ISANAPPLICATIONEXAMPLEOFADHESIVEBONDINGFORMICROOPTICALSWITCHTHEPROCESSOFADHESIVEBONDINGSTARTSWITHAPPLYINGTHEADHESIVELAYER,FOLLOWEDBYCONTACTINGTHEWAFERSANDFORMINGBONDBYAHEATCURING,ORULTRAVIOLETUVCURING4OPTICALFIBERSUBSTRATECERAMICPLATE2CERAMICPLATE1GLASSCAPADHESIVEFIG3ADHESIVEPACKAGINGFORMICROOPTICALSWITCHADHESIVESAREWIDELYUSEDINPACKAGINGFORMOEMS,SUCHASTACKING,FILLINGANDSEALINGTHEPRECISIONSTRUCTURE,JOININGTHECERAMICFRAMES,GLASSLIDANDPCBSUBSTRATESTOFORMAHERMETICPACKAGEHOWEVER,ITISDIFFICULTTOOBTAINUNIFORMANDHERMETICBONDINGWITHVACUUMGRADEANDHUMIDITYINSENSITIVEDUETOTHEPERMEATIONOFMOISTUREWECOULDCHOOSEANADHESIVEMATERIALWITHLOWPERMEATIONRATEORCOATANANTIPERMEATIONLAYERSUCHASSIO2TORESOLVESUCHAPROBLEM23GLASSFRITBONDINGTHEADVANTAGEOFGLASSFRITBONDINGISTHECAPABILITYOFPRODUCINGGOODHERMETICSEALSDEVELOPMENTOFAGLASSFRITBONDINGPROCESSISTOUSEANINBETWEENGLASSLAYERATTEMPERATURESBELOW400CBYCOMBININGANODICBONDINGWITHGLASSFRITCOATINGONWAFERSINVARIOUSMATERIALS,SUCHASSILICON,CERAMICANDMETAL,ITISPOSSIBLETOANODICALLYBONDWAFERSEXCEPTGLASSWAFERWITHSILICONWAFERBESIDES,ITCANBEUSEDINHERMETICBONDINGBETWEENCERAMICLAYERSFIG4ISONEEXAMPLEOFITSAPPLICATIONSILICONLIDGLASSFRITSUBSTRATEFIG4SCHEMATICPACKAGINGOFGLASSFRITBONDINGTHEPROCESSCANBEDESCRIBEDASBELOWFIRSTAPPLYTHEFRITPASTEONTOTHESUBSTRATEWITHMEMSCHIPSTHROUGHSCREENPRINTPROCESSAFTERTHATTHEFRITMUSTBETHOROUGHLYDRIEDOVENDRYINGCANBEUSEDTHENRAISETHETEMPERATURETOAROUND400C,THESOFTENINGPOINTOFTHEFRIT,ANDHOLDFOR5TO10MINUTESBEFORECOOLINGDOWNSEALINGCYCLESDEPENDSONTHEGEOMETRYANDSIZEOFSEALINGINTERFACETHEIMPORTANTPARAMETERSOFHEATINGPROCESSARESTARTINGPOINTFOREXPERIMENTATION,SEALINGTEMPERATURE,HOLDINGTEMPERATURE,ANDHEATINGRATEOFEACHSTEP,WHICHSHOULDBEFOLLOWEDTHESPECIFICATIONGIVENBYTHEFRITSUPPLIERITISNECESSARYTOMAINTAINANOXIDIZINGENVIRONMENTATALLTIMESINTHEFURNACE24ANODICBONDINGANODICBONDINGCANBEUSEDTOBONDTWOMATERIALS,SUCHASSILICONANDGLASS,SILICONANDSILICON,CERAMICANDMETAL,ETCINRECENTYEARS,ANODICBONDINGHASBEENWIDELYAPPLIEDTOVACUUMPACKAGINGOFMEMSDEVICESITISARELIABLEANDEFFECTIVEPROCESSFORHERMETICALLYSEALINGSILICONWAFERSTOGLASSWAFERSORQUARTZSUBSTRATESANODICBONDINGISUSUALLYCARRIEDOUTUNDERCONSTANTTEMPERATUREANDVOLTAGETHECATHODEMAKESCONTACTWITHTHEGLASSWAFER,WHILETHEANODECONNECTSTOTHESILICONWAFERBYHEATINGAT200500CANDSUPPLYING2001500VOLTSDCVOLTAGEACROSSASILICONGLASSWAFERSTACK,THEPOSITIVEIONSINTHEGLASS,MAINLYSODIUMIONSWHICHCOMEFROMTHEDISSOCIATIONOFNAO2,MOVETOTHECATHODE,LEAVINGTHENONBRIDGINGOXYGENIONSTHEOXYGENIONSBONDEDTOONLYONESILICONATOMBEHINDCONSEQUENTLY,ANEGATIVELYCHARGEDDEPLETIONLAYERISFORMEDADJACENTTOTHEANODETHEELECTROSTATICFORCEBETWEENTHISNEGATIVELAYERANDTHEPOSITIVECHARGESINDUCEDAROUNDTHEANODEMAKESTHETWOSIDESINTIMATELYCONTACTWITHEACHOTHERTHISFORCE,ALLIEDTOTHESOFTENINGOFTHEGLASS,ALLOWSSOMECONFORMINGOFGLASSTOTHEOPPOSINGSURFACEANDMAKESPOSSIBLEHERMETICALLYBONDINGBETWEENSURFACESTHATAREIMPERFECTALOWTEMPERATUREANODICBONDINGFORHERMETICSEALINGWASDEVELOPEDTHEINTERFACEINTEGRITYWASOBSERVEDUNDERSCANNINGELECTRONMICROSCOPESEMFIG5SHOWSATYPICALCROSSSECTIONOFBONDEDSIANDGLASSITPROVESTHATSILICONANDGLASSWEREDENSELYBONDEDTOGETHERFIG5ATYPICALCROSSSECTIONOFBONDEDSIANDGLASSMEASUREMENTOFTHEDISTRIBUTIONOFTHEELEMENTSSI,OANDNAINTHEINTERFACEBETWEENSIANDGLASSALSOSHOWSTHATSICONTENTDECREASESWHILEOCONTENTINCREASESFROMSIWAFERSIDETOGLASSWAFERSIDENOOBVIOUSCHANGEWASFOUNDFORNAELEMENTTHEREASONISTHATLOWTEMPERATUREWASUSEDINOURBONDINGPROCESSALTHOUGHNAMAYMIGRATETOCATHODE,THEMIGRATIONLEVELISMUCHLOWERTHANTHATATHIGHTEMPERATURE25HERMETICBONDINGWITHIMPERFECTSURFACETHEELECTRICALFEEDTHROUGHS,WHICHLINKTOTHEOUTSIDEOFTHESEALEDSTRUCTURE,MAKETHESURFACEOFTHESUBSTRATEIMPERFECTTHEREFORE,THEHERMETICPACKAGINGWITHELECTRICALFEEDTHROUGHSISANESSENTIALCONSIDERATIONFORMANYMICROSYSTEMS5,6THEELECTRICALFEEDTHROUGHSAREGENERALLYREQUIREDTOCONNECTAMICROSENSINGORACTUATINGELEMENTFROMTHEINSIDEOFTHESEALEDSTRUCTURETOTHEOUTSIDEWORLDFOREXAMPLE,ELECTRICALPOWERNEEDSTOBESUPPLIEDTOTHESEALEDREGIONANDELECTRICALSENSINGSIGNALSNEEDTOBEEXTRACTEDFROMTHESEALEDPACKAGELATERALELECTRICALFEEDTHROUGHSOFMETALCONDUCTORSARECOMMONLYUSEDFORALONGTIMETHESTANDARDFABRICATIONPROCESSINSEMICONDUCTORINDUSTRY,SUCHASELECTRONICPLATING,VAPORDEPOSITIONANDSPUTTERING,MAKESTHELATERALELECTRICALFEEDTHROUGHTECHNIQUEVERYCONVENIENTHOWEVER,THICKMETALCOATINGONTHEINTERFACEOFSILICONWAFERORGLASSWAFERWILLRESULTSINFAILUREINANODICBONDINGBETWEENSILICONANDGLASSDUETOTHEAIRLEAKAGEORDEBONDINGFROMTHEBONDINGINTERFACETHEREARETWOAPPROACHESTOREALIZEHERMETICSEALINGVIAANODICBONDINGOFSILICONTOGLASSWITHTHICKMETALFEEDTHROUGHONTHESURFACES7THEYARETHEPATTERNEDEMBEDEDELECTRODEANDTHEVERTICALVIAELECTRODEMETHODFORINTERCONNECTIONOFMEMSDEVICESFIG6APROCESSFLOWOFTHEEMBEDEDELECTRODEMETHODTHEFABRICATIONPROCESSOFEMBEDEDELECTRODEMETHODISSHOWNINFIG6BOTHGLASSANDSILICONWAFERSAREAVAILABLEINTHEPROCESSFIRSTAPATTERNEDSHALLOWTRENCHWASETCHEDONTHESURFACEOFTHEWAFERSECONDFORSILICONWAFER,ANADDITIONALSIO2FILMWASDEPOSITEDINORDERTOFORMANINSULATIONLAYERAFTERTHAT,METALWASDEPOSITEDONTHEPATTERNEDWAFERTOFORMEMBEDDEDTHICKELECTRODESINSIDETHETRENCHCHEMICALMECHANICALPOLISHINGCMPPROCESSWASTHENCARRIEDOUTTOFORMASMOOTHANDLEVELEDBONDINGSURFACEFINALLY,THESILICONANDGLASSWAFERSWEREBONDEDTOGETHERBYANODICBONDINGTESTRESULTSHOWSTHATAFTERCMPTHEROUGHNESSOFTHEGLASSWAFERPLANARIZATIONISASLOWAS13NM,WHICHISGOODENOUGHFORSILICONTOGLASSANODICBONDINGWITHHERMETICSEALINGTHEEMBEDEDELECTRODESBOTHONGLASSWAFERANDSILICONWAFERHAVEBEENSUCCESSFULLYFABRICATEDTHEWIDTHOFTHEELECTRODESCANBEFABRICATEDFROM20MTO80M,ANDTHETHICKNESSFROM05MTO19MUSINGMEMSPRESSURESENSORTOINVESTIGATETHEHERMETICITY,WEFOUNDTHATTHELEVELEDANDPOLISHEDGLASSWAFERWITHEMBEDEDELECTRODEWASANODICALLYBONDEDWITHSILICONWAFERTHEOTHERAPPROACHISCALLEDTHEVERTICALVIAELECTRODEMETHODMICROSTRUCTUREWASFABRICATEDTHROUGHSTANDARDMEMSPROCESSANDANODICBONDINGAFTERETCHINGOFVIAHOLES,VERTICALELECTRODESWEREFORMEDTHROUGHTHEVIASBYDEPOSITIONANDPATTERNINGOFMETALFILMTHEN,AMETALVIAPROCESSWASAPPLIEDTOFORM3DELECTRICINTERCONNECTIONATTHESAMETIME,ITALSOSERVESASTHEHERMETICSEALINGPROCESSBYFILLINGMETALMATERIALINTOTHEVIASFINALLY,POSTPROCESSES,SUCHASFILLINGPOLYMERINSULATIONPI,DEPOSITINGUBMANDWAFERBUMPING,WEREPERFORMEDANDTHREEDIMENSION3DINTERCONNECTIONBYVIASWASFORMEDFIG7SHOWSAMICROGRAPHOFANELECTRICVIAONSILICONWAFERVERTICALINTERCONNECTIONBOTTOMELECTRODEPIVIATOPELECTRODEFIG7AMICROGRAPHOFANELECTRICVIAONSIWAFER3VACUUMMAINTENANCEFORMEMSPACKAGINGAFTERHERMICSEALING,THEINNERWALLSOFTHESMALLSCALECAVITYMIGHTRELEASEGAS,WHICHAFFECTTHEVACUUMMAINTENANCEWITHTHEADVANTAGEOFHIGHSORBINGCAPABILITY,COMMERCIALNONEVAPORABLEGETTERNEGHASBEENUSEDINVACUUMMAINTENANCEOFELECTRONICPACKAGINGITISPREPAREDBYCOATINGGETTERMATERIALSONSTRIPSORSHEETSANDCUTTHEMINTOTHEDESIRABLESHAPEANDSIZEBYMECHANICALCUTTINGORBYLASERBEAMTHENTHENEGISFASTENEDONTHEINNERSURFACEOFDEVICESSTRUCTUREHOWEVER,ITISDIFFICULTTOAPPLYTHECOMMERCIALNEGTOMAINTAINHIGHERVACUUMENVIRONMENTINMICROSCALECAVITYINORDERTOMATCHWITHTHEMINIATURIZATIONOFMEMSDEVICESTHEMETHODOFDEPOSINGTHINFILMORTHICKFILMOFGETTERMATERIALSONTOINNERSURFACEOFMICROSTRUCTURESBECOMESASOLUTIONTOMAINTAINVACUUMINMICROCAVITY8,9ASCHEMATICOFTHEKEYPROCESSSTEPSISPRESENTEDINFIG8THEPREPROCESSCONSISTSOFMASKDESIGN,MAKINGOFGETTERPASTEBYMIXINGK4SI,GRAPHITEWITHPOWDEROFZRVFEALLOY,ANDTHEFABRICATIONOFMEMSCHIPFIRST,PRINTGETTERPASTEONTHESURFACEOFDOUBLESIDEPOLISHEDPYREX7740GLASSWAFERTOFORMAPATTERNTHENCOATNEGTHICKFILMONTHESURFACEAFTERPREBAKINGAT120CFORHALFANHOUR,THEGLASSWAFERANDSILICONWAFERWITHMEMSSTRUCTUREARECLEANEDTOELIMINATEPARTICLESANDOTHERCONTAMINATIONONTHESURFACESANODICBONDINGWASTHENAPPLIEDTOHERMETICALLYJOINTHEGLASSWAFERTOTHESILICONWAFERTHEBONDINGPROCESSWASCARRIEDOUTWITHEV501BONDERATAPRESSUREOF1103TORRANDDCVOLTAGEOF1000VOLTSFOR60MINUTESTHEBONDINGTEMPERATUREIS450CWETESTEDTHESORPTIONCAPABILITYTOEXAMINETHEPERFORMANCEOFTHEGETTERFILMEXPERIMENTALPRESSUREVARIATIONAGAINSTTIMEISSHOWNINFIG9GOODSORPTIONCAPABILITYOF488106PASCALLITRE/M2HASBEENMEASUREDWITHTHEGETTERINGOF65PALITRE/SFIG8PACKAGINGFLOWFORMEMSWITHTHICKFILMNEGFIG9SORPTIONCAPABILITYTESTPRESSUREVARIATIONVSTIMETHEFLASHINGGETTERMATERIALHASALSOBEENUSEDINTHEMEMSPACKAGINGRESEARCHBECAUSEOFITSATTRACTIVEFEATURES,SUCHASSTEADYPERFORMANCE,CONSISTENTYIELDOFGETTERINGMATERIALSANDMINIMALOUTGASSINGDURINGEVAPORATIONBYEVAPORATIONITCANBEEASILYDEPOSITEDONTOTHEINNERWALLSOFTHEMICROCAVITYINTHEFORMOFTHINFILMTHEGETTERUSEDINOURRESEARCHISCOMMERCIALLYAVAILABLEUNDERTHETRADENAMEOFBI5U1HFG21,WHOSEACTIVEINGREDIENTSAREBA,ALANDNIALLOYSBESIDESITSHIGHEFFICIENTADSORPTIONPERFORMANCE,THEEXPERIMENTALRESULTSALSOSHOWTHATITHASTHEGOODADHESIONOFTHETHINFILMTHETHICKNESSOFGETTERFILMCOATEDONTHEWAFERCANBECONTROLLEDINTHERANGEOFSEVERALTOHUNDREDSMICRONSBYADJUSTINGTHEHEATERTEMPERATUREANDPROCESSTIMEITISALSOFEASIBLETOFORMAPATTERNEDGETTERFILMONTHELIDSURFACEUSINGAPHYSICALMASKBETWEENGETTERSOURCEANDTHETARGET4CONCLUSIONSSILICONGOLDEUTECTICBONDINGFORMSASOFTEUTECTICTOALLOWBONDINGOVERNONPLANARSURFACES,ITCANBEDONEATABOVETHEEUTECTICTEMPERATURE363C,ANDITSELFDOESNOTHAVETHEOUTGASSINGPROBLEMTHATOTHERAPPROACHESPRODUCEADHESIVEBONDINGHASALOWPROCESSTEMPERATUREANDITC
温馨提示
- 1. 本站所有资源如无特殊说明,都需要本地电脑安装OFFICE2007和PDF阅读器。图纸软件为CAD,CAXA,PROE,UG,SolidWorks等.压缩文件请下载最新的WinRAR软件解压。
- 2. 本站的文档不包含任何第三方提供的附件图纸等,如果需要附件,请联系上传者。文件的所有权益归上传用户所有。
- 3. 本站RAR压缩包中若带图纸,网页内容里面会有图纸预览,若没有图纸预览就没有图纸。
- 4. 未经权益所有人同意不得将文件中的内容挪作商业或盈利用途。
- 5. 人人文库网仅提供信息存储空间,仅对用户上传内容的表现方式做保护处理,对用户上传分享的文档内容本身不做任何修改或编辑,并不能对任何下载内容负责。
- 6. 下载文件中如有侵权或不适当内容,请与我们联系,我们立即纠正。
- 7. 本站不保证下载资源的准确性、安全性和完整性, 同时也不承担用户因使用这些下载资源对自己和他人造成任何形式的伤害或损失。
最新文档
- 2026年福建省石狮市高一数学下册期末考试模拟考试卷附答案【基础题】
- 2026年宁波市北仑区事业编单位人员招聘笔试参考试题及答案详解
- 2026年陕西省汉中市社区工作者招聘笔试备考试题及答案详解
- 2026年伊春市西林区网格员招聘考试备考题库及答案详解
- 2026年河南省许昌市社区工作者招聘笔试备考试题及答案详解
- 2026年乌鲁木齐市沙依巴克区社区工作者招聘笔试参考试题及答案详解
- 2026年秦皇岛市山海关区社区工作者招聘考试模拟试题及答案详解
- 2026年河北省唐山市社区工作者招聘笔试备考试题及答案详解
- 2026年克拉玛依市独山子区网格员招聘笔试备考题库及答案详解
- 2026年日喀则地区日喀则市事业编单位人员招聘考试参考试题及答案详解
- 石油化工工程建设设计概算编制办法
- 数据库应用技术-第三次形考作业(第10章~第11章)-国开-参考资料
- 低温甲醇洗脱硫脱碳技术
- 国家开放大学理工英语1(12套)
- 外墙三明治板施工方案
- 国家开放大学《工作分析实务》形考任务1-4参考答案
- 新课标-人教版四年级数学上册第三单元《角的度量》教材分析
- 护理会诊制度及查房制度课件
- GB/T 42598-2023机械安全使用说明书起草通则
- 大学英语六级词汇表(全)含音标
- 农业银行境外汇款申请书样板
评论
0/150
提交评论